基于多频磁负超材料的心脏起搏器无线供能研究

doi:10.19595/j.cnki.1000-6753.tces.230969

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摘要针对植入式心脏起搏器无线供能系统频率变化发生共振失调导致传输效率低等问题,该文提出一种基于多频磁负超材料（MB-MNG）的心脏起搏器无线供能系统。首先,根据磁负超材料等效介质理论,推导了正八边形超材料设计的基本公式,建立了MB-MNG基元模型;其次,以S-S结构为例,通过仿真和实验研究了6.78 MHz、8.94 MHz和13.56 MHz频段下系统传输效率;再次,为了研究可靠性,讨论了系统与MB-MNG之间的错位情况;最后,为确保安全性,使用多物理场仿真软件研究系统的电磁安全特性,并进行温升实验。实验结果表明：在三工作频段下,基于MB-MNG的WPT系统的输出功率为3.29 W、2.77 W和2.87 W,与传统WPT系统和加入铁氧体薄板WPT系统对比,传输效率提高了24.6%~36.5%。同时,在系统发生偏移时,仍能保持30.73%~48.41%的传输效率;60 min充电测试内组织SAR值及最大温升均符合安全标准。

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关键词 ：无线供能系统, 多频磁负超材料, 心脏起搏器, 传输性能

Abstract：Magnetic coupled resonant wireless power transfer (MCR-WPT) technology is a safer choice for powering implanted medical devices. However, MCR-WPT systems incorporating traditional metamaterials usually work at a fixed single frequency. When the system operating frequency changes, frequency detuning and electromagnetic leakage are prone to occur. , reducing transmission efficiency. Based on the above problems, this paper designs a multi-frequency magnetic negative metamaterial used in implantable cardiac pacemakers' wireless energy supply system. Adjusting the patch capacitance connected in the elementary coil can realize the operation at 6.78 MHz, 8.94 MHz, and 13.56 MHz multi-frequency reduces the impact of frequency detuning, ensuring higher working efficiency while avoiding magnetic field leakage.
First, based on the equivalent medium theory of magnetic negative metamaterials, the basic formula for the design of regular octagonal metamaterials was deduced, the multi-band magnetic negative metamaterial (MB-MNG) primitive model was established, the parameters of the metamaterial primitives were determined, and the lumped capacitance value of the series connection between the primitives was determined. The metamaterial primitives have special electromagnetic properties at multiple operating frequencies of 6.78 MHz, 8.94 MHz, and 13.56 MHz, changing the direction of the passing magnetic field, laying a theoretical foundation for metamaterials to achieve negative refraction.
Secondly, taking the S-S structure as an example, simulation verified that the equivalent magnetic permeability of the metamaterial element in the 6.78 MHz, 8.94 MHz, and 13.56 MHz frequency bands is negative and the direction of the magnetic field changes. The designed multi-frequency magnetic negative metamaterial is added to the MCR-WPT system and the magnetic field distribution of the traditional MCR-WPT system is comparatively studied. The simulation results show that after adding the multi-frequency magnetic negative metamaterial array, the transmission efficiency under the three operating frequency bands is 43.2%, 60.8%, and 75.9%. Compared with the WPT system without adding metamaterials, the transmission efficiency increases by 14.2%~22.1%. When the receiving coil is horizontally offset, after adding multi-frequency magnetic negative metamaterials, the system can still maintain transmission efficiencies of 19.3%, 42.9%, and 56.5%. This shows that the addition of multi-frequency magnetic negative metamaterials improves the transmission performance of the pacemaker wireless power transmission system in the event of horizontal offset and enhances the tolerance of system misalignment.
An implantable pacemaker wireless power supply experimental system based on the MB-MNG array was built and compared with the MCR-WPT system adding ferrite sheets and the traditional MCR-WPT system. The experimental results show that when the transmission distance is 20 mm and the operating frequencies are 6.78 MHz, 8.94 MHz and 13.56 MHz, the output powers of the MCR-WPT system adding the multi-frequency magnetic negative metamaterial array are 3.29 W, 2.77 W and 2.87 respectively. W, the system transmission efficiency is 66.7%, 48.6% and 51.9% respectively. Compared with the addition of ferrite sheets and the traditional MCR-WPT system, the transmission efficiency has increased by 11.5%~28.0% and 24.6%~36.5% respectively; in the receiving coil, In the case of horizontal offset, the MCR-WPT system with multi-frequency magnetic negative metamaterial array increased the transmission efficiency by 14.68%~26.27% compared with the traditional system; the temperature rise experiment verified that the maximum temperature rise of the system is 3.3℃, which will not pose a threat to human safety. Therefore, the application of the multi-frequency magnetic negative metamaterial array proposed in this article to the implantable pacemaker wireless energy supply system can effectively improve the system transmission efficiency and anti-excursion capability, while reducing magnetic field leakage and ensuring human life safety.

Key words： Wireless power transfer (WPT) multi-band magnetic negative metamaterial (MB-MNG) cardiac pacemakers transmission performance

收稿日期: 2023-06-16

PACS:

TM724

基金资助:2020年辽宁省教育厅科学研究青年科技人才“育苗”项目（LJ2020QNL019）、2023年辽宁省教育厅科学技术研究面上项目《基于磁负超材料的心脏起搏器无线供能系统传输特性研究》（JYTMS20230815）资助

通讯作者: 黄雨琦女,1998年生,硕士,研究方向为无线电能传输技术。E-mail：2410423184@qq.com

作者简介: 陈伟华男,1980年生,博士,副教授,研究方向为无线电能传输技术。E-mail：fxlgd@163.com

引用本文:

陈伟华, 黄雨琦, 闫孝姮, 宋佳伟. 基于多频磁负超材料的心脏起搏器无线供能研究[J]. 电工技术学报, 2024, 39(16): 4931-4943. Chen Weihua, Huang Yuqi, Yan Xiaoheng, Song Jiawei. Wireless Energy Supply for Cardiac Pacemaker Based on Multi-Band Magnetic Negative Metamaterial. Transactions of China Electrotechnical Society, 2024, 39(16): 4931-4943.

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